JP6149317B2 - Winding glass ribbon with tension applied to the interlayer material - Google Patents

Description

Explanation of related applications

  This application claims the benefit of priority of US Provisional Patent Application No. 61 / 417,908, filed Nov. 30, 2010, the contents of which are incorporated herein by reference in their entirety. Is.

  The present invention relates to a method and apparatus for winding a glass ribbon. More specifically, the present invention relates to a method and apparatus for winding a glass ribbon with an interlayer material to form a roll.

  Glass formed as a continuous ribbon is typically divided into sheet glass as soon as it cools and solidifies. There has been a demand for thinner glass from recent product trends—for example, electronic paper (ePaper) front substrates, photovoltaic module protective cover sheets, touch sensors, solid state lighting, and electronic equipment. However, as the glass thickness continues to decrease, these sheets become more flexible. For this reason, in particular, a glass having a thickness of 0.3 mm or less has a problem from the viewpoint of handling. Therefore, as a method for facilitating handling, attempts have been made to wind thin glass around a roll. However, glass has several unique features that pose challenges to the successful execution of the winding process.

  First, when an edge “bead” is formed in the glass, the bead is significantly thicker than the constant thickness area between the edges. Second, glass is extremely sensitive to surface defects. These defects create stress points that can generate cracks and lead to breakage. That is, as is typical for rollers wound with material, it is not recommended that the surface of the glass itself be in direct contact. The challenges of these first two properties have already been addressed by using various slip-sheet materials between the layers when winding the glass ribbon.

  Third, the inventors of the subject matter in this disclosure have noticed and have not yet been addressed—with respect to the effect on the winding of thin glass ribbons, ie, ribbons of 0.3 mm or less— It is possible to cause thickness differences across the width of the glass ribbon and / or warpage (continuous curvature in one direction caused by differences in cooling between the two edge beads). Winding a glass ribbon having a thickness difference and / or warpage across the ribbon creates a transverse force on the wound roll, which causes the rolled roll to have inclined sidewalls rather than straight. Arise. In some cases, the angle of the side wall can cause the glass ribbon to contact the flange of the spool that is winding the glass ribbon, thereby risking damage to the glass ribbon. Furthermore, when the roll is unwound to use a glass ribbon in a continuous manufacturing process, the inclined sidewalls of the roll make the process difficult. Therefore, there is a need for a method and apparatus for winding a glass ribbon with an interlayer material so that the roll has straight side walls.

  In order to form rolled glass ribbon rolls with straight side walls, we have selected the winding conditions, especially the effects of thickness differences and / or warpage across the ribbon. I found that it can be weakened by doing. Appropriate winding conditions include web tension when the roll is formed, interlayer pressure in the roll, and how to apply tension while winding the interlayer material and the glass ribbon to form the roll.

  More specifically, we have typical web winding process parameters of 0.18 to 0.36 kg / cm (1-2 lb / linear inch) web tension, and 0.1 to It has been found that using an interlayer pressure of 0.35 MPa (15-50 pounds per square inch) with a thin glass ribbon and interlayer material produces sloped sidewalls on the roll. Furthermore, contrary to conventional common sense (which dictates the use of high tension and interlaminar pressure to achieve better handling, storage, and density for wound products), web tension In addition, the present inventors have found that when the pressure between the glass ribbon and the interlayer material is increased, the characteristics of the sidewall are actually deteriorated. Surprisingly, the inventors have found that using lower web tension and lower interlayer pressure produces straight sidewalls on the roll. More specifically, the web tension is more than 0 kg / cm and not more than 0.045 kg / cm (0.25 lb / linear inch), and the interlayer pressure in the roll is more than 0 MPa and not more than 0.07 MPa (10 lb / square). If it is less than an inch), a straight side wall is generated in the wound thin glass. In another embodiment, straight sidewalls are produced in the roll even when the interlayer pressure in the roll is greater than 0 MPa and less than or equal to 0.05 MPa (7 pounds per square inch). Furthermore, it is desirable to maintain the interlayer pressure within the roll substantially constant throughout the roll.

  Furthermore, the present inventors have found that how to apply tension while winding the interlayer material and the glass ribbon affects the straightness of the side wall of the roll obtained. More specifically, tension should be applied to the interlayer material rather than the glass ribbon. That is, almost no tension should be applied to the glass ribbon. More specifically, the tension due to the weight of the ribbon itself in the free loop used to separate the upstream and winding processes should be the only tension applied to the glass ribbon. If any significant tension is applied to the glass ribbon itself (ie, other than due to frictional resistance within the roller forming the free loop, and other than the weight of the ribbon itself in the free loop), warping and The effect of thickness variation is magnified, leading to undesirable, inclined, dished and / or telescopic side walls in the resulting roll. The tension applied to the interlayer material should be less than or equal to 0.045 kg / cm (0.25 lb / linear inch) (in terms of width) as described above. Further, the tension should be decreased in response to an increase in the diameter of the roll (ie, the roll containing the glass ribbon and the interlayer material) and / or in response to a decrease in the diameter of the interlayer supply roll. If tension is not reduced with roll diameter, the interlaminar pressure within the roll will increase and more and more pressure will be applied. When excessively high pressure occurs, the properties of the roll sidewalls deteriorate.

  Furthermore, if the type of the interlayer material itself is conveniently selected, the influence of the thickness variation of the glass ribbon can be reduced. More specifically, if the interlayer material is thickness compliant, or if the interlayer material has some elasticity upon compression, the thickness of the interlayer material that may be present in the glass ribbon. Can be absorbed. The appropriate stiffness of the interlayer material is about 28.14 N / mm or less, or about 27.12 N / mm or less, or about 26.1 N / mm or less, and the lower limit of all the ranges at this time is more than 0 It was found. In order to achieve the rigidity described above, the interlayer material may be formed, for example, from foamed polyethylene (open cell or closed cell), corrugated paper material, or a sheet of soft polyvinyl material having an embossed or roughened surface.

  Furthermore, an apparatus for winding a glass ribbon together with an interlayer material on a roll is disclosed. This device is provided along an interlayer material supply path, a glass ribbon supply path, a roll winding mechanism, and an interlayer material supply path so as to generate pressure between the layers of the roll when the interlayer material is wound around the roll. Tension applying means for applying tension to the moving interlayer material. By applying appropriate tension to the interlayer material, a suitable pressure is created between the layers of glass ribbon and interlayer material in the roll so that a roll having straight sidewalls can be produced. The tension applying means may be, for example, a pneumatic brake, a mechanical friction brake, a magnetic powder brake, an electric brake, or a servo motor. Further, the tension applying means may be connected to a roll for supplying the interlayer material, or may be connected to the interlayer material moving along the supply path directly or through a roller or a roller system. An appropriate controller is connected to the tensioning means and received from a sensor that measures one or both of the amount of interlayer material on the interlayer material supply roll or the amount of material wound on the roll of glass ribbon and interlayer material. According to the input, the controller may control the tension applying means.

  Additional features and advantages will be set forth in the detailed description which follows, and in part will be readily apparent to those skilled in the art from the description, or may be described in the written description or accompanying drawings as illustrated. It will be appreciated by practicing the invention. The foregoing general description and the following detailed description are exemplary only of the present invention and are intended to provide an overview or arrangement for understanding the nature and characteristics of the claimed invention. I want you to understand.

  The accompanying drawings are included to provide a further understanding of the principles of the invention, and are incorporated in and constitute a part of this specification. The drawings illustrate one or more embodiments, and together with the description, serve to explain, by way of example, the principles and operations of the invention. It should be understood that the various features of the invention disclosed in this document and the drawings can be used in any combination and all in combination. By way of non-limiting example, the various features of the present invention may be combined with each other as in the following embodiments.

According to a first aspect, there is provided a method of winding a glass ribbon, the method comprising:
Winding together the interlayer material and the glass ribbon to produce a roll; and
Applying tension to the interlayer material to control the interlayer pressure of the roll when winding the interlayer material and the glass ribbon;
including.

According to a second aspect, there is provided a method of winding a glass ribbon, the method comprising:
Winding the interlayer material and the glass ribbon together to produce a roll having a substantially constant roll interlayer pressure;
including.

  According to a third aspect, the method of aspect 2 is provided, characterized in that the roll interlayer pressure is controlled by applying tension to the interlayer material.

  According to a fourth aspect, there is provided the method of any one of aspects 1 to 3, wherein the winding step is wound to form the nip of the interlayer material by winding the interlayer material on the core at least once. And inserting a glass ribbon into the nip.

  According to a fifth aspect, the method of aspect 1 or aspect 3 is provided, wherein the step of applying tension is controlled to decrease the tension in response to an increase in roll diameter.

  According to a sixth aspect, the method of aspect 1 or aspect 3 is provided, further comprising the step of unwinding the interlayer material from the interlayer material roll, and the tension is reduced in response to a decrease in the diameter of the interlayer material roll. It is characterized by controlling.

  According to a seventh aspect, the method of aspect 6 is provided and further comprises the step of measuring the diameter of the interlayer material roll.

  According to an eighth aspect, the method of aspect 1, 5 or 6 is provided, wherein the step of applying tension is controlled to produce an approximately constant roll interlayer pressure between the interlayer material and the glass ribbon. It is characterized by that.

  According to a ninth aspect, there is provided the method of aspect 2 or aspect 8, characterized in that the interlaminar pressure of the roll is 0.07 MPa or less (10 pounds per square inch or less) and greater than 0 MPa. .

  According to a tenth aspect, there is provided the method of aspect 2 or aspect 8, characterized in that the interlaminar pressure of the roll is 0.05 MPa or less (7 pounds per square inch or less) and greater than 0 MPa. .

  According to an eleventh aspect, any one of the aspects 1 to 10 is provided, wherein the thickness of the glass ribbon is 0.3 mm or less.

  According to a twelfth aspect, there is provided the method according to any one of aspects 1 to 11, wherein the interlayer material is a material that flexibly corresponds to the thickness.

  According to a thirteenth aspect, the method of aspect 12 is provided, wherein the interlayer material is a foamed polyethylene sheet having a rigidity of 28.14 N / mm or less.

  According to a fourteenth aspect, there is provided the method of any one of aspects 1 to 13, characterized in that the glass ribbon forms a free loop before being wound with the interlayer material.

  According to a fifteenth aspect, the method of aspect 14 is provided, characterized in that the only tension that pulls the glass ribbon when the glass ribbon is wound with the interlayer material is that generated in the free loop. To do.

  According to a sixteenth aspect, there is provided a method according to any one of aspects 1 to 15, characterized in that tension is applied to the interlayer material by a pneumatic brake or servo motor coupled to the interlayer material.

  According to a seventeenth aspect, there is provided the method of any one of aspects 1 to 16, wherein the step of applying a tension is 0.045 kg / cm (0. 25 pounds / linear inch) or less.

According to an eighteenth aspect, there is provided a method of manufacturing a glass article, the method comprising:
Forming a glass ribbon; and
Winding a glass ribbon according to any one of aspects 1 to 17,
including.

  According to a nineteenth aspect, there is provided the method of aspect 18, characterized in that the glass ribbon is formed by a downdraw process.

According to a twentieth aspect, there is provided an apparatus for winding a glass ribbon together with an interlayer material on a roll.
Interlayer material supply path,
Glass ribbon supply path,
Roll winding mechanism, and
A tension applying means for applying tension to the interlayer material moving along the interlayer material supply path so as to generate pressure between the layers of the roll when the interlayer material is wound around the roll;
It has.

  According to a twenty-first aspect, there is provided the apparatus according to aspect 20, wherein the tension applying means is one of a pneumatic brake and a servo motor coupled to the interlayer material.

  According to a twenty-second aspect, an apparatus according to aspect 20 or aspect 21 is provided, further comprising a measuring instrument positioned to measure the diameter of the roll.

  According to a twenty-third aspect, there is provided the apparatus according to aspect 22, further comprising a controller coupled to the measuring instrument and the tension applying means, wherein the controller is configured to control the tension applied to the interlayer material in response to an increase in the diameter of the roll. The tension applying means is controlled so as to decrease the tension.

  According to a twenty-fourth aspect, there is provided an apparatus according to any one of aspects 20-23, wherein the measuring instrument is positioned to measure the diameter of an interlayer material roll that supplies the interlayer material along the interlayer material supply path Is further provided.

  According to a twenty-fifth aspect, there is provided an apparatus according to aspect 24, further comprising a controller coupled to the measuring instrument and the tension applying means, wherein the controller reduces the tension applied to the interlayer material by reducing the diameter of the interlayer material roll. The tension applying means is controlled so as to decrease in accordance with the above.

  According to a twenty-sixth aspect, there is provided an apparatus according to any one of aspects 20 to 25, wherein the tension applying means applies a tension greater than 0 and less than or equal to 0.045 kg / cm (0.25 lb / linear inch). It is characterized by that.

Schematic side view of a device that winds a glass ribbon around a roll together with an interlayer material Sectional view of the roll along line 2-2 in FIG. Plan view of the apparatus shown in FIG. Top view of glass ribbon

  In the following detailed description, for purposes of explanation and not limitation, example embodiments disclosing specific details are set forth in order to provide a thorough understanding of various principles of the invention. It will be apparent, however, to one of ordinary skill in the art who has benefited from the present disclosure that the present invention may be practiced in other embodiments that depart from the specific details disclosed herein. Moreover, descriptions of well-known devices, methods, and materials may be omitted so as not to obscure the description of various principles of the invention. Finally, wherever applicable, the same reference numbers indicate similar elements.

  In this document, ranges may be expressed from “about” one particular value and / or “about” another particular value. When a range is expressed in this way, another embodiment includes from the one particular value and / or to the other particular value. Similarly, when values are expressed as approximations, using the antecedent “about,” it should be understood that that particular value forms another embodiment. It should be further understood that the endpoints of each range are important in relation to the other endpoint and are also important independent of the other endpoint.

  The terms used in this document, such as up, down, right, left, front, back, top, bottom, etc., are based solely on the picture being drawn and are absolute orientations. It is not intended to include meaning.

  Unless explicitly stated otherwise, any method specified herein is not intended to be construed as requiring that the steps be performed in any particular order. Thus, if the method claims do not actually describe the order in which the steps follow, or if the steps or claims do not specifically state that the steps are limited to a particular order Is not intended in any way to infer the order. This includes all possible manifestations, including logic issues regarding the placement of steps or operational flows, obvious meanings derived from grammar construction or punctuation, and the number or type of embodiments described herein. It is applied as a principle of interpretation that is not done.

  In this document, the singular includes the plural reference unless the context clearly dictates otherwise. That is, for example, reference to “a component” includes aspects having two or more of this component unless the context clearly indicates otherwise.

  Here, the apparatus which winds a glass ribbon with a interlayer material on a roll is demonstrated. This device is provided along an interlayer material supply path, a glass ribbon supply path, a roll winding mechanism, and an interlayer material supply path so as to generate pressure between the layers of the roll when the interlayer material is wound around the roll. Tension applying means for applying tension to the moving interlayer material. By applying appropriate tension to the interlayer material, a suitable pressure is created between the layers of glass ribbon and interlayer material in the roll so that a roll having straight sidewalls can be produced. Further, the tension applying means may be connected to a roll for supplying the interlayer material, or may be connected to the interlayer material moving along the supply path directly or through a roller or a roller system. An appropriate controller is connected to the tensioning means and received from a sensor that measures one or both of the amount of interlayer material on the interlayer material supply roll or the amount of material wound on the roll of glass ribbon and interlayer material. According to the input, the controller may control the tension applying means.

  Here, an embodiment of an apparatus for winding a glass ribbon around a roll together with an interlayer material will be described with reference to FIGS.

  FIG. 1 is a schematic view of an apparatus for winding a glass ribbon 10 together with an interlayer material 20. The apparatus includes a roller 18 for guiding the glass ribbon 10 and a roller 30 for guiding the interlayer material 20. The rollers 18 and 30 guide the glass ribbon 10 and the interlayer material 20 along their respective supply paths toward positions where they can be wound together around the roll 40.

  As shown in FIGS. 1-2, the roll 40 may include a core 42 having a central longitudinal axis 43 with respect to the central longitudinal axis 43 that rotates in the direction of arrow 44. A cross section of roll 40 is shown in FIG. 2, which is taken along line 2-2 of FIG. 1, but omits the top layer of interlayer material for clarity of illustration. As shown in FIG. 2, the roll 40 comprises a glass ribbon 10, an interlayer material 20, and optionally a core 42 around which the glass ribbon 10 and the interlayer material 20 are wound in alternating layers. Including. Although the roll 40 is illustrated as having three layers of the glass ribbon 10 and the interlayer material 20, the number of each layer in the roll can be any appropriate number.

  Returning to FIG. 1, a sensor 48 is disposed to measure the amount of glass ribbon 10 and interlayer material 20 disposed on the roll 40. This measurement may be made by measuring the diameter or radius of the material on the roll 40. For example, the sensor 48 may be an ultrasonic sensor, a laser sensor, or a contact sensor. A roll winding mechanism 46 (see FIG. 3) is schematically shown as being coupled to the core 42 by arrows 47 to rotate the core 42 about the shaft 43. The winding mechanism 46 may be a motor, such as, for example, a servo motor, a stepping motor, or a clutch drive motor, and the winding mechanism 46 may be controlled by any suitable controller known in the industry.

  The interlayer material 20 has a width 21 and is supplied in the direction of the arrow 25 from the interlayer material supply roll 22. The roll 22 has a central longitudinal axis 23 and the roll 22 rotates in the direction of arrow 24 so that the interlayer material 20 is pulled to the roll 40. As shown in FIG. 3, the pneumatic brake 26 is connected to the interlayer material supply roll 22 to control the rotation of the interlayer material supply roll 22, that is, when the interlayer material 20 is wound around the roll 40. Tension is applied to 20. A suitable pneumatic brake is available from Nexen, headquartered in Vadnais, Minn. The sensor 28 is arranged to measure the amount of the interlayer material 20 arranged on the roll 22. Similar to sensor 48, sensor 28 may be, for example, an ultrasonic sensor, a laser sensor, or a contact sensor, which measures the diameter or radius of the material of roll 22. As described above, if the interlayer material itself is conveniently selected, it is possible to reduce the influence of the thickness variation of the glass ribbon. More specifically, when the interlayer material 20 flexibly corresponds to the thickness, or when the interlayer material 20 has some elasticity when compressed, the interlayer material 20 can have a thickness that can exist in the glass ribbon 10. Can be absorbed. The appropriate rigidity of the interlayer material 20 is about 28.14 N / mm or less, or about 27.12 N / mm or less, or about 26.1 N / mm or less, and the lower limit of all the ranges at this time is more than 0 It was found that there was. In order to achieve the rigidity described above, the interlayer material 20 may be formed of, for example, foamed polyethylene (open cell or closed cell), corrugated paper material, or a sheet of soft polyvinyl material having an embossed or roughened surface.

  The controller 50 is coupled to the sensor 48 via a path 52 and is coupled to the sensor 28 via a path 54. Further, the controller is connected to the control valve 60 by a path 56. The controller 50 may be, for example, a programmable logic controller, or a general-purpose computer or a dedicated computer. A suitable programmable logic controller is available from Allan Bradley, a division of Rockwell Automation, headquartered in Milwaukee, Wis. When the controller 50 is a general-purpose computer or a dedicated computer, the controller 50 may be further connected to the winding mechanism 46 to control the device. Paths 52, 54, and 56 may be wires that conduct electrical signals or conduits that conduct fluids (eg, pneumatic or hydraulic). The control valve 60 may be, for example, a pneumatic proportional valve or an electrically controlled proportional valve. Suitable control valves are available from SMC headquartered in Noblesville, IN.

  The control valve 60 is connected to the fluid source at path 62 and to the pneumatic brake 26 at path 64. Control valve 60 receives fluid at a constant pressure along path 62 and varies the pressure of the fluid exiting along path 64 in response to a signal received from controller 50 along path 56. Can do.

  A method of forming a roll of glass ribbon and interlayer material having straight sidewalls is further described. The method includes controlling tension in terms of the amount applied to the material being wound and in terms of how it is applied to the material being wound. More specifically, a relatively low amount of tension (greater than 0 and less than or equal to 0.045 kg / cm (0.25 lb / linear inch) width) is applied during the winding of the material, and this tension is also applied to the glass ribbon. Without being added to the interlayer material. By controlling the amount and manner in which tension is applied to the wound material, the appropriate pressure can be created between the layers of the rolls to achieve straight sidewalls on the rolls.

  One embodiment of a method of forming a roll of glass ribbon and interlayer material having straight sidewalls will now be described in connection with FIGS.

  The glass ribbon 10 may be fed directly from an upstream process, such as a forming process--for example, a downdraw, slot draw, fusion draw, updraw, or float process--or a process of conveying the glass ribbon in use. Supplied from any kind of transport process including. In either case, the glass ribbon 10 is fed from the upstream process along the direction 15 toward the roll 40 rotating in the direction 44. Before reaching the roll 40, the glass ribbon 10 enters a free loop 19 formed between the guide rollers 18. The free loop 19 separates the upstream process from the winding process, i.e. compensates for the difference in the moving speed of the glass ribbon between the upstream process and the winding process. Almost simultaneously with supplying the glass ribbon 10 toward the roll 40, the interlayer material 20 is unwound from the roll 22 rotating in the direction 24 and supplied along the direction 25. The interlayer material 20 is positioned with respect to the roll 40 using the guide roller 30. According to one aspect, the interlayer material 20 is wound around the core 42 (see FIG. 2) one or more times before the glass ribbon 10 is fed into the nip 45 between successive layers of the interlayer material 20. According to another aspect, the interlayer material 20 may be fed into the nip between successive layers of the glass ribbon 10 after the glass ribbon 10 is first wound around the core 42. In either case, the glass ribbon 10 and the interlayer material 20 are wound together in alternating layers to form a roll 40 around the core 42. The core 42 may remain in the roll 40 or may be removed from the roll 40. When leaving the core 42 in the roll 40, the innermost layer (either the interlayer material or the glass ribbon) may be attached to the core 42. Holding the wick 42 in the roll 40 and attaching the interlayer 20 to the wick 42 helps prevent the entire wound glass / interlayer pack from slipping sideways during unrolling in subsequent process steps. It becomes.

  FIG. 4 is a top view of the glass ribbon 10 that may be produced by any suitable method, such as, for example, downdraw, fusion draw, updraw, slotdraw, or float, as described above. The thickness 4 (see FIG. 2) of the glass ribbon 10 may be from about 50 μm to about 300 μm, and its edges 3a, 3b include the as-formed edges (including beads as shown in FIG. 2). Or a cut edge (not shown, but with the beads removed). The ribbon forming process can cause variations in thickness across the width of the ribbon, as well as “warping” in the movement of the ribbon. FIG. 4 shows a glass ribbon 10 exhibiting a warp 5 (in this figure, it is greatly exaggerated for explanation). As can be seen, the warp 5 is a continuous bow of the ribbon in one direction (ie, to the left in FIG. 4). This curvature may be caused, for example, by differences in the cooling rate of the ribbon edge beads. Due to the warp, thickness variation, and residual stress of the glass ribbon, the ribbon may be displaced laterally without being conveyed linearly. If you try to wind the glass ribbon around the roll, this lateral displacement will cause the roll side to be "dish", "telescope", or any other non-straight shape, i.e. , Each of the edges 3a, 3b will generally be positioned substantially in one plane.

  In order to overcome the effects of warpage and / or thickness variations, the winding parameters for making roll 40 are selected as specified below. The winding parameters include how tension is applied to the material being wound, the amount of tension, and the pressure obtained between the layers of the roll. These parameters may be useful with each other alone, or may be useful in any combination and all combinations based on various circumstances.

  First, tension is applied to the interlayer material 20 rather than the glass ribbon 10. Attempting to apply any significant amount of tension to the glass ribbon 10 as the glass ribbon 10 is wound causes the side walls of the roll 40 to “dish” due to warpage and / or thickness variations of the glass ribbon 10. The present inventors have found that the shape is “telescopic”, “telescopic”, or any other non-straight shape. Thus, the only tension applied to the glass ribbon 10 when it is wound is that resulting from its own weight in the free loop 19. However, on the other hand, when the interlayer material 20 is wound with the glass ribbon 10, it is desirable to apply tension to the interlayer material 20 in order to produce a roll 40 having substantially straight side walls. Found.

  The tension applied to the interlayer material 20 is established by the pneumatic brake 26. The pneumatic brake 26 is connected to the roll 22, and when the interlayer material 20 is wound together with the glass ribbon 10, the pneumatic brake 26 provides a force that resists the traction force of the roll 40 to the interlayer material 20. Thus, tension can be applied to the interlayer material 20 by controlling the pneumatic brake 26. In the illustrated embodiment, the pneumatic brake 26 is controlled by the controller 50 via the control valve 60. For example, in a pneumatic system, the control valve 60 is a proportional control valve connected to a constant pressure air source in a path 62. Control valve 60 further receives an input signal from controller 50 via path 56. The signal from the controller 50 may be based on an input from the sensor 28 or may be based on an input from the sensor 48. Thereafter, the control valve 60 outputs the air whose pressure has been reduced by an amount based on the signal input from the controller 50 along the path 64. When the controller 50 uses the measurement results from the sensor 48 to generate an output signal to the control valve 60, the control valve 60 reduces the pressure along the path 64 as the diameter of the roll 40 increases. On the other hand, when the controller 50 uses the measurement result from the sensor 28 to generate an output signal to the control valve 60, the control valve 60 reduces the pressure along the path 64 as the diameter of the roll 22 decreases. . In either case, the pressure along path 64 decreases. In response to the reduced pressure in path 64, pneumatic brake 26 reduces the braking force applied to roll 22. Accordingly, the tension of the interlayer material 20 can be reduced in response to either an increase in the diameter of the roll 40 or a decrease in the diameter of the roll 22, including maintaining the proper pressure between the roll 40 layers. Is more beneficial.

  The signal from the sensor 28 may further be used to adjust the amount of tension established by the pneumatic brake 26 at the beginning of the winding operation after the initial loading of the roll 22 of interlayer material 20. For example, when the roll 22 is first loaded into the winding device, it will not always be in its full state. Therefore, by measuring the size of the roll 22 with the sensor 28 before starting the winding operation of the roll 22 after the roll 22 is loaded, the tension established by the pneumatic brake 26 is set to a value suitable for the size of the roll 22 (controller). 50). Once the size of the roll 22 is known, the controller 50 can select the appropriate amount of braking to cause the interlayer material 20 to produce a desired amount of tension when the interlayer material 20 is unwound. Similarly, a signal from the sensor 48 may be used to adjust the amount of tension at the time when the roll 40 starts to be wound. That is, when the sensor 48 detects the diameter of the roll 40 indicating the new roll 40, the controller 50 can adjust the force applied by the pneumatic brake 26 so as to generate a tension suitable for starting the roll 40. Again, as described above, the amount of tension applied to the interlayer material 20 may be reduced as the material on the roll 40 subsequently increases.

  Second, the amount of tension applied to the interlayer material 20 is selected to be less than or equal to 0.045 kg / cm (0.25 lb / linear inch) with respect to the width 21 of the interlayer material 20. More specifically, typical web winding process parameters of 0.18-0.36 kg / cm (1-2 lb / linear inch) web tension, and 0.1-0.35 MPa (15- The inventors have found that using an interlayer pressure of 50 pounds per square inch with a thin glass ribbon 10 and interlayer material 20 produces sloped sidewalls on the roll. Furthermore, the present inventors have found that contrary to conventional common sense, when the web tension and the interlayer pressure increase, the characteristics of the sidewall are actually deteriorated. Surprisingly, we use lower web tension (and apply that tension to the interlayer material 20) and even lower interlayer pressure (of the glass ribbon 10 and interlayer material 20). And found that a straight side wall is produced on the roll 40. More specifically, when the tension applied to the interlayer material 20 is more than 0 kg / cm and not more than 0.045 kg / cm (0.25 lb / linear inch), a straight side wall is generated on the roll 40.

  As noted above, in order to maintain adequate interlayer pressure, particularly in the roll 40, it is advantageous to reduce the amount of tension applied to the interlayer material 20 as the size of the roll 40 increases. Since the above tension range is given by the force per unit width, the total amount of tension directly depends on the width 21 of the interlayer material 20. That is, the total amount of tension is simply the pound per inch multiplied by the inch of the width 21 of the interlayer 20. On the other hand, the tension applied to the interlayer material 20 is generally independent of the speed at which the roll 40 rotates.

  Third, the interlayer pressure of the glass ribbon 10 and the interlayer material 20 in the roll 40 as a result of the winding conditions described above also plays a role in the generation of the roll 40 having straight sidewalls. By controlling the above-described winding conditions, the interlayer pressure in the obtained roll 40 can be maintained at more than 0 and 0.07 MPa or less (10 pounds / square inch or less). According to another aspect, the interlaminar pressure in the roll 40 can be maintained above 0 and 0.05 MPa or less (7 pounds per square inch or less). As described above, if the pressure between the layers of the roll 40 (glass ribbon 10 and interlayer material 20) is maintained within the noted range, a roll 40 having straight sidewalls can be conveniently produced. In addition, it is desirable to maintain a substantially constant interlayer pressure through the roll 40.

A glass ribbon having a thickness of 150 μm was wound around a roll together with an interlayer material. The interlayer material was irradiated crosslinked ethylene vinyl acetate (EVA) copolymer of 0.079 cm (1/32 inch) thick, 280 mm (11 inch) wide, and a density of 0.1 grams / cubic centimeter (6 pounds / cubic foot). Foam (available as FLEXcon PEF 32 white no PS from FLEXcon, Spencer, Mass.). The interlayer material was wound around a roll core (nominal diameter 508 mm (20 inches), minimum diameter 457 mm (18 inches), maximum diameter 610 mm (24 inches)) to start the roll, and then formed with the interlayer material A glass ribbon was fed into the nip. The roll winding parameters were as follows.
● Roll winding speed is 381-853.4 cm / min (12.5-28 ft / min)
● The diameter of the completed roll (when measured up to the outermost layer of the glass ribbon and the interlayer material) is less than 29 inches. The braking torque applied to the interlayer material roll is 0.56 Nm (5 inches at the start of winding) -Lbs) and decreased to 0.11 Nm (1 in-lb) at the end of winding.
Interlayer roll diameter ranges from 559 mm (22 inches) (320 m (1050 ft) on the roll) to 470 mm (18.5 inches) (213 m (700 ft) on the roll)
The tension applied to the interlayer material is approximately 0.011 to 0.022 kg / cm (0.06 to 0.12 lb / linear inch)
● Measured interlayer pressure in the resulting roll is less than 0.05 MPa (7 pounds per square inch) —a pressure indicating sensor film (FujiFilm) placed between the glass ribbon layer and the interlayer material layer ), Distributed by Sensor Products Inc., Japan) Lower limit of detection ● Controller 50 is Allen-Bradley model RS Logix 500 from Rockwell Automation, Milwaukee, Wisconsin, USA
● Pneumatic brake 26 is Nexen model 800113
● The control valve 60 is an SMC electronic regulator.
When the rolls of glass ribbon and interlayer material were wound using the above parameters and equipment, the rolls had straight sidewalls.

  Both the glass ribbon and the interlayer material are wound on a roll, and at this time, a tension of about 0.013 kg / cm (0.07 lb / linear inch) is applied to the interlayer material at the start of winding the pneumatic brake 0.62 Nm The same procedure and equipment as specified in Example 1 except that (5.5 in-lbs) torque, 0.084 MPa (12 psi), was set in the entire winding process. This increased the tension linearly to 0.09 kg / cm (0.5 pounds / linear inch) by the end of winding. The side walls of the rolls of glass ribbon and interlayer material were not straight.

  It should be emphasized that the above-described embodiments of the present invention, particularly any "preferred" embodiments, are merely possible examples and are merely illustrative for a clear understanding of the various principles of the invention. Many variations and modifications may be made to the above-described embodiments of the invention without departing substantially from the spirit and various principles of the invention. All such modifications and variations are intended to be included herein within the scope of this disclosure and the present invention and protected by the following claims.

  For example, the illustrated core 42 does not have a flange at its end, but may have a flange. Further, the flange may be permanently attached to the core 42 or may be removable.

  Further, although the three layers of interlayer material 20 and the three layers of glass ribbon 10 are illustrated as being wound on a roll 40, any suitable number of layers can be present.

  Further, although pneumatic examples have been given for illustration purposes, other methods and equipment may be used. For example, instead of using a pneumatic brake, a servo motor that operates in a torque mode may be used, and this may be controlled by changing the input current. When the servo motor is used, the proportional control valve is not pneumatic, and the proportional control valve is omitted when the controller 50 can perform appropriate control, such as when the controller 50 is a general-purpose computer or a dedicated computer. be able to. Furthermore, the pneumatic brake can be replaced by any other suitable type of tensioning device, such as a mechanical friction brake, a magnetic powder brake, an electric brake, or a servomotor. Any of these devices that apply tension to the interlayer material moving along the interlayer material supply path to create pressure between the layers of the roll when the interlayer material is wound on the roll 40, It serves as a means for applying tension to the interlayer material.

  In addition, the illustrated pneumatic brake is directly connected to the roll of interlayer material, but instead, either a pneumatic brake, servo motor, or other tensioning device can be attached to the interlayer material using a separate roller or roller system. You may connect. Such a roller system may be integrated with the guide roller 30 that guides the interlayer material 20 in the direction of the arrow 25 along the supply path. The web of interlayer material may be further wrapped around the roller with a load cell incorporated in the bearing mount. These load cells may be calibrated to directly measure the tension of the interlayer material and this information may then be used in the control system to maintain the proper tension as described above. One consideration is that the tensioning means applies tension to the interlayer material to create pressure between the interlayer material and the glass ribbon layer when the interlayer material is wound with the glass ribbon. . By maintaining the proper interlayer pressure within the roll, a roll with straight sidewalls is produced.

DESCRIPTION OF SYMBOLS 10 Glass ribbon 18, 30 Guide roller 20 Interlayer material 22 Interlayer material supply roll 26 Pneumatic brake 28, 48 Sensor 40 Roll 42 Core 45 Nip 46 Winding mechanism 50 Controller 60 Control valve

Claims (9)

In the method of winding a glass ribbon,
Winding together the interlayer material and the glass ribbon to produce a roll; and
Applying tension to the interlayer material when winding the interlayer material and the glass ribbon;
Including
The interlayer material and the glass ribbon are supplied via different supply paths,
A free loop for reducing tension applied to the glass ribbon is provided in the supply path of the glass ribbon,
The interlayer material is supplied from an interlayer material supply roll,
A brake mechanism that applies a braking force to the interlayer material supply roll is connected to the interlayer material supply roll so as to provide a force that resists the traction force of winding.
In the step of applying the tension, the tension is applied to the interlayer material by the brake mechanism.   The step of applying the tension includes applying the tension to the interlayer material so that the interlayer pressure of the roll is controlled to 0.07 MPa (10 pounds per square inch) or less and more than 0 MPa. Item 2. The method according to Item 1.   The method according to claim 1, wherein the interlayer material is a material that flexibly corresponds to a thickness.   The method according to claim 3, wherein the interlayer material is a foamed polyethylene sheet having a rigidity of 28.14 N / mm or less.   The step of applying the tension is performed such that when the interlayer material is wound on the roll, it produces a tension of 0.045 kg / cm (0.25 lb / linear inch) or less on the interlayer material. 5. A method according to any one of claims 1 to 4, characterized in that A method of manufacturing a glass article,
Forming a glass ribbon; and
Winding the glass ribbon according to the method of any one of claims 1 to 5,
A method comprising the steps of: In an apparatus that winds a glass ribbon around a roll together with an interlayer material,
Interlayer material supply path including interlayer material supply roll,
Glass ribbon supply path,
Roll winding mechanism, and
A tension applying means for applying a tension to the interlayer material moving along the interlayer material supply path when the interlayer material is wound around the roll;
With
The tension applying means includes a brake mechanism connected to the interlayer material supply roll so as to apply a braking force to the interlayer material supply roll so as to provide a force resisting the traction force of the roll winding mechanism;
The glass ribbon supply path is provided with a free loop for reducing tension applied to the glass ribbon,
A device characterized by that.   The tension applying means applies the tension to the interlayer material so as to generate a pressure of 0.07 MPa (10 pounds per square inch) or less and more than 0 MPa between the layers of the rolls. The apparatus of claim 7.   9. The apparatus according to claim 7, wherein the tension applying means applies a tension of more than 0 and not more than 0.045 kg / cm (0.25 lb / linear inch).

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